mightyscape-1.1-deprecated/extensions/fablabchemnitz/svgpathtools/parser.py

"""This submodule contains the path_parse() function used to convert SVG path
element d-strings into svgpathtools Path objects.
Note: This file was taken (nearly) as is from the svg.path module
(v 2.0)."""

# External dependencies
from __future__ import division, absolute_import, print_function
import re

# Internal dependencies
from .path import Path, Line, QuadraticBezier, CubicBezier, Arc


COMMANDS = set('MmZzLlHhVvCcSsQqTtAa')
UPPERCASE = set('MZLHVCSQTA')

COMMAND_RE = re.compile("([MmZzLlHhVvCcSsQqTtAa])")
FLOAT_RE = re.compile(r"[-+]?[0-9]*\.?[0-9]+(?:[eE][-+]?[0-9]+)?")


def _tokenize_path(pathdef):
    for x in COMMAND_RE.split(pathdef):
        if x in COMMANDS:
            yield x
        for token in FLOAT_RE.findall(x):
            yield token


def parse_path(pathdef, current_pos=0j):
    # In the SVG specs, initial movetos are absolute, even if
    # specified as 'm'. This is the default behavior here as well.
    # But if you pass in a current_pos variable, the initial moveto
    # will be relative to that current_pos. This is useful.
    elements = list(_tokenize_path(pathdef))
    # Reverse for easy use of .pop()
    elements.reverse()

    segments = Path()
    start_pos = None
    command = None

    while elements:

        if elements[-1] in COMMANDS:
            # New command.
            last_command = command  # Used by S and T
            command = elements.pop()
            absolute = command in UPPERCASE
            command = command.upper()
        else:
            # If this element starts with numbers, it is an implicit command
            # and we don't change the command. Check that it's allowed:
            if command is None:
                raise ValueError("Unallowed implicit command in %s, position %s" % (
                    pathdef, len(pathdef.split()) - len(elements)))

        if command == 'M':
            # Moveto command.
            x = elements.pop()
            y = elements.pop()
            pos = float(x) + float(y) * 1j
            if absolute:
                current_pos = pos
            else:
                current_pos += pos

            # when M is called, reset start_pos
            # This behavior of Z is defined in svg spec:
            # http://www.w3.org/TR/SVG/paths.html#PathDataClosePathCommand
            start_pos = current_pos

            # Implicit moveto commands are treated as lineto commands.
            # So we set command to lineto here, in case there are
            # further implicit commands after this moveto.
            command = 'L'

        elif command == 'Z':
            # Close path
            if not (current_pos == start_pos):
                segments.append(Line(current_pos, start_pos))
            segments.closed = True
            current_pos = start_pos
            start_pos = None
            command = None  # You can't have implicit commands after closing.

        elif command == 'L':
            x = elements.pop()
            y = elements.pop()
            pos = float(x) + float(y) * 1j
            if not absolute:
                pos += current_pos
            segments.append(Line(current_pos, pos))
            current_pos = pos

        elif command == 'H':
            x = elements.pop()
            pos = float(x) + current_pos.imag * 1j
            if not absolute:
                pos += current_pos.real
            segments.append(Line(current_pos, pos))
            current_pos = pos

        elif command == 'V':
            y = elements.pop()
            pos = current_pos.real + float(y) * 1j
            if not absolute:
                pos += current_pos.imag * 1j
            segments.append(Line(current_pos, pos))
            current_pos = pos

        elif command == 'C':
            control1 = float(elements.pop()) + float(elements.pop()) * 1j
            control2 = float(elements.pop()) + float(elements.pop()) * 1j
            end = float(elements.pop()) + float(elements.pop()) * 1j

            if not absolute:
                control1 += current_pos
                control2 += current_pos
                end += current_pos

            segments.append(CubicBezier(current_pos, control1, control2, end))
            current_pos = end

        elif command == 'S':
            # Smooth curve. First control point is the "reflection" of
            # the second control point in the previous path.

            if last_command not in 'CS':
                # If there is no previous command or if the previous command
                # was not an C, c, S or s, assume the first control point is
                # coincident with the current point.
                control1 = current_pos
            else:
                # The first control point is assumed to be the reflection of
                # the second control point on the previous command relative
                # to the current point.
                control1 = current_pos + current_pos - segments[-1].control2

            control2 = float(elements.pop()) + float(elements.pop()) * 1j
            end = float(elements.pop()) + float(elements.pop()) * 1j

            if not absolute:
                control2 += current_pos
                end += current_pos

            segments.append(CubicBezier(current_pos, control1, control2, end))
            current_pos = end

        elif command == 'Q':
            control = float(elements.pop()) + float(elements.pop()) * 1j
            end = float(elements.pop()) + float(elements.pop()) * 1j

            if not absolute:
                control += current_pos
                end += current_pos

            segments.append(QuadraticBezier(current_pos, control, end))
            current_pos = end

        elif command == 'T':
            # Smooth curve. Control point is the "reflection" of
            # the second control point in the previous path.

            if last_command not in 'QT':
                # If there is no previous command or if the previous command
                # was not an Q, q, T or t, assume the first control point is
                # coincident with the current point.
                control = current_pos
            else:
                # The control point is assumed to be the reflection of
                # the control point on the previous command relative
                # to the current point.
                control = current_pos + current_pos - segments[-1].control

            end = float(elements.pop()) + float(elements.pop()) * 1j

            if not absolute:
                end += current_pos

            segments.append(QuadraticBezier(current_pos, control, end))
            current_pos = end

        elif command == 'A':
            radius = float(elements.pop()) + float(elements.pop()) * 1j
            rotation = float(elements.pop())
            arc = float(elements.pop())
            sweep = float(elements.pop())
            end = float(elements.pop()) + float(elements.pop()) * 1j

            if not absolute:
                end += current_pos

            segments.append(Arc(current_pos, radius, rotation, arc, sweep, end))
            current_pos = end

    return segments
Initial commit 2020-07-30 01:16:18 +02:00			`"""This submodule contains the path_parse() function used to convert SVG path`
			`element d-strings into svgpathtools Path objects.`
			`Note: This file was taken (nearly) as is from the svg.path module`
			`(v 2.0)."""`

			`# External dependencies`
			`from __future__ import division, absolute_import, print_function`
			`import re`

			`# Internal dependencies`
			`from .path import Path, Line, QuadraticBezier, CubicBezier, Arc`


			`COMMANDS = set('MmZzLlHhVvCcSsQqTtAa')`
			`UPPERCASE = set('MZLHVCSQTA')`

			`COMMAND_RE = re.compile("([MmZzLlHhVvCcSsQqTtAa])")`
different large refactorings (subdirectores, removed obsolete stuff) and bug fixes 2020-08-31 21:25:41 +02:00			`FLOAT_RE = re.compile(r"[-+]?[0-9]*\.?[0-9]+(?:[eE][-+]?[0-9]+)?")`
Initial commit 2020-07-30 01:16:18 +02:00

			`def _tokenize_path(pathdef):`
			`for x in COMMAND_RE.split(pathdef):`
			`if x in COMMANDS:`
			`yield x`
			`for token in FLOAT_RE.findall(x):`
			`yield token`


			`def parse_path(pathdef, current_pos=0j):`
			`# In the SVG specs, initial movetos are absolute, even if`
			`# specified as 'm'. This is the default behavior here as well.`
			`# But if you pass in a current_pos variable, the initial moveto`
			`# will be relative to that current_pos. This is useful.`
			`elements = list(_tokenize_path(pathdef))`
			`# Reverse for easy use of .pop()`
			`elements.reverse()`

			`segments = Path()`
			`start_pos = None`
			`command = None`

			`while elements:`

			`if elements[-1] in COMMANDS:`
			`# New command.`
			`last_command = command # Used by S and T`
			`command = elements.pop()`
			`absolute = command in UPPERCASE`
			`command = command.upper()`
			`else:`
			`# If this element starts with numbers, it is an implicit command`
			`# and we don't change the command. Check that it's allowed:`
			`if command is None:`
			`raise ValueError("Unallowed implicit command in %s, position %s" % (`
			`pathdef, len(pathdef.split()) - len(elements)))`

			`if command == 'M':`
			`# Moveto command.`
			`x = elements.pop()`
			`y = elements.pop()`
			`pos = float(x) + float(y) * 1j`
			`if absolute:`
			`current_pos = pos`
			`else:`
			`current_pos += pos`

			`# when M is called, reset start_pos`
			`# This behavior of Z is defined in svg spec:`
			`# http://www.w3.org/TR/SVG/paths.html#PathDataClosePathCommand`
			`start_pos = current_pos`

			`# Implicit moveto commands are treated as lineto commands.`
			`# So we set command to lineto here, in case there are`
			`# further implicit commands after this moveto.`
			`command = 'L'`

			`elif command == 'Z':`
			`# Close path`
			`if not (current_pos == start_pos):`
			`segments.append(Line(current_pos, start_pos))`
			`segments.closed = True`
			`current_pos = start_pos`
			`start_pos = None`
			`command = None # You can't have implicit commands after closing.`

			`elif command == 'L':`
			`x = elements.pop()`
			`y = elements.pop()`
			`pos = float(x) + float(y) * 1j`
			`if not absolute:`
			`pos += current_pos`
			`segments.append(Line(current_pos, pos))`
			`current_pos = pos`

			`elif command == 'H':`
			`x = elements.pop()`
			`pos = float(x) + current_pos.imag * 1j`
			`if not absolute:`
			`pos += current_pos.real`
			`segments.append(Line(current_pos, pos))`
			`current_pos = pos`

			`elif command == 'V':`
			`y = elements.pop()`
			`pos = current_pos.real + float(y) * 1j`
			`if not absolute:`
			`pos += current_pos.imag * 1j`
			`segments.append(Line(current_pos, pos))`
			`current_pos = pos`

			`elif command == 'C':`
			`control1 = float(elements.pop()) + float(elements.pop()) * 1j`
			`control2 = float(elements.pop()) + float(elements.pop()) * 1j`
			`end = float(elements.pop()) + float(elements.pop()) * 1j`

			`if not absolute:`
			`control1 += current_pos`
			`control2 += current_pos`
			`end += current_pos`

			`segments.append(CubicBezier(current_pos, control1, control2, end))`
			`current_pos = end`

			`elif command == 'S':`
			`# Smooth curve. First control point is the "reflection" of`
			`# the second control point in the previous path.`

			`if last_command not in 'CS':`
			`# If there is no previous command or if the previous command`
			`# was not an C, c, S or s, assume the first control point is`
			`# coincident with the current point.`
			`control1 = current_pos`
			`else:`
			`# The first control point is assumed to be the reflection of`
			`# the second control point on the previous command relative`
			`# to the current point.`
			`control1 = current_pos + current_pos - segments[-1].control2`

			`control2 = float(elements.pop()) + float(elements.pop()) * 1j`
			`end = float(elements.pop()) + float(elements.pop()) * 1j`

			`if not absolute:`
			`control2 += current_pos`
			`end += current_pos`

			`segments.append(CubicBezier(current_pos, control1, control2, end))`
			`current_pos = end`

			`elif command == 'Q':`
			`control = float(elements.pop()) + float(elements.pop()) * 1j`
			`end = float(elements.pop()) + float(elements.pop()) * 1j`

			`if not absolute:`
			`control += current_pos`
			`end += current_pos`

			`segments.append(QuadraticBezier(current_pos, control, end))`
			`current_pos = end`

			`elif command == 'T':`
			`# Smooth curve. Control point is the "reflection" of`
			`# the second control point in the previous path.`

			`if last_command not in 'QT':`
			`# If there is no previous command or if the previous command`
			`# was not an Q, q, T or t, assume the first control point is`
			`# coincident with the current point.`
			`control = current_pos`
			`else:`
			`# The control point is assumed to be the reflection of`
			`# the control point on the previous command relative`
			`# to the current point.`
			`control = current_pos + current_pos - segments[-1].control`

			`end = float(elements.pop()) + float(elements.pop()) * 1j`

			`if not absolute:`
			`end += current_pos`

			`segments.append(QuadraticBezier(current_pos, control, end))`
			`current_pos = end`

			`elif command == 'A':`
			`radius = float(elements.pop()) + float(elements.pop()) * 1j`
			`rotation = float(elements.pop())`
			`arc = float(elements.pop())`
			`sweep = float(elements.pop())`
			`end = float(elements.pop()) + float(elements.pop()) * 1j`

			`if not absolute:`
			`end += current_pos`

			`segments.append(Arc(current_pos, radius, rotation, arc, sweep, end))`
			`current_pos = end`

			`return segments`